CN108828786A

CN108828786A - A kind of 3D camera

Info

Publication number: CN108828786A
Application number: CN201810646394.6A
Authority: CN
Inventors: 吕方璐
Original assignee: Shenzhen Guang Jian Technology Co Ltd
Current assignee: Shenzhen Guang Jian Technology Co Ltd
Priority date: 2018-06-21
Filing date: 2018-06-21
Publication date: 2018-11-16
Also published as: CN110161713A; CN210090835U; CN210129072U

Abstract

The present invention relates to a kind of 3D cameras, including structured light projection instrument, infrared camera, RGB camera and diffuser；Diffuser is set to the light emission side of structured light projection instrument, and diffuser includes two layers of transparent electrode and the diffusion barrier that is located between two layers of transparent electrode, and the material of diffusion barrier is liquid crystal/polymer composite materials；Diffuser transparent mode in the state of making alive, structured light projection instrument can issue random array light to target object through diffuser, diffuser is in dispersal pattern in the state that voltage is not added, and structured light projection instrument can issue uniform light to target object by diffuser；RGB camera in bright light environments for capturing the 2D image of target object surface；Infrared camera is used for the random dot matrix photogenerated depth image according to target object surface, and captures the 2D image of target object surface under uniform light in a dark environment.The 3D camera can be effectively reduced cost and realize miniaturization.

Description

A kind of 3D camera

Technical field

The present invention relates to depth sensing equipment technical fields, and in particular to a kind of 3D camera.

Background technique

In recent years, with the continuous development of consumer electronics industry, the 3D camera with depth sensing function increasingly by The attention of consumer electronics circle.The depth measurement method of comparative maturity is structure light scheme at present, i.e., by specific structured light patterns It is projected on object, the depth of object different location is then calculated by the deformation of pattern or displacement.

Infrared 2D image is formed due to being also required in a dark environment, it is red that general 3D camera requires additionally configuration one Outer washers illuminate the object in dark, while recording infrared 2D image with infrared camera.Infrared washers one As be made of one or more infrared lasers and diffusion barrier, the setting of infrared washers not only increases entire 3D The cost and power consumption of camera, are unfavorable for the miniaturization of 3D camera.

Therefore, how to reduce the cost of 3D camera and realize miniaturization, be the skill that those skilled in the art need to solve Art problem.

Summary of the invention

The object of the present invention is to provide a kind of 3D cameras, can be effectively reduced cost and realize miniaturization.

In order to solve the above technical problems, the present invention provides a kind of 3D camera comprising structured light projection instrument, infrared photography Head, RGB camera and diffuser；The diffuser is set to the light emission side of the structured light projection instrument, and the diffuser includes two Layer transparent electrode and the diffusion barrier being located between two layers of transparent electrode, the material of the diffusion barrier are liquid crystal/polymerization Object composite material；The diffuser transparent mode in the state of making alive, the structured light projection instrument can be through described Diffuser issues random array light to target object, and the diffuser is in dispersal pattern, the knot in the state that voltage is not added Structure light projector can issue uniform light to the target object by the diffuser；The RGB camera is used for bright The 2D image of the target object surface is captured in environment；The infrared camera be used for according to target object surface with Machine dot matrix photogenerated depth image, and the 2D figure of the target object surface is captured under the uniform light in a dark environment Picture.

The diffusion barrier of liquid crystal/polymer composite materials is placed between two layers of transparent electrode, it can be by being applied to diffusion barrier Making alive changes the optical characteristics of this layer of liquid crystal/polymer composite materials.When to diffuser making alive, the direction of liquid crystal Along direction of an electric field, diffusion barrier is in transparent mode, is equivalent to transparent material layer, so that structure light be made to pass through liquid crystal For layer without scattering, structure light does not have any change.When voltage is not added in diffuser, the direction random distribution of liquid crystal, diffusion barrier It in dispersal pattern, is scattered when structure light passes through liquid crystal layer, incident light is diffused into equally distributed illumination to be equivalent to (i.e. above-mentioned uniform light) output.

Specifically, diffuser is in alive situation when being measured by the 3D camera to the depth of target object Under, diffusion barrier is in transparent mode, structured light projection instrument can be directed through the diffuser to the surface of target object issue with Machine array light, infrared camera measures the illumination patterns situation on the surface of target object, and combines possessed by random array light The depth image of specific distribution situation generation target object；And two kinds of feelings are divided into for the capture of the 2D image of target object surface Condition, the first situation are that the 2D image of target object surface, second of feelings can be captured by RGB camera in bright light environments Condition is that in a dark environment, for diffuser in the case where voltage is not added, diffusion barrier is in dispersal pattern, and structured light projection instrument is sent out Random array light out is radiated at the uniform light of target object surface by the diffuser by scattering, at this point, structured light projection The uniform light of instrument only plays illuminating effect, under the illumination of uniform light, can capture target object surface by infrared camera 2D image；Finally, being the 3D rendering for producing the target object according to the depth image of target object surface and 2D image.

Diffusion barrier is selected to be in transparent mode or dispersal pattern, the diffuser by the way that whether electricity control diffuser pressurizes Setting the acquisition of depth image is not influenced, also, acquire target object surface 2D image when, which can also Enough so that structured light projection instrument plays illuminating effect, without in addition setting illuminace component (such as infrared washers), also It is to say, by the setting of the diffuser, so that structured light projection instrument can not only issue random array light to target object, simultaneously The function of illumination is also had both, the overall structure of the 3D camera can be simplified and is conducive to the miniaturization of 3D camera.Simultaneously because expanding The thinner thickness of film and transparent electrode is dissipated, small volume is readily integrated to the light emission side of structured light projection instrument, right in the present embodiment Connection between structured light projection instrument and diffuser with no restrictions, can such as pass through splicing or the clamping of other mechanical parts The fixation of equal realizations position between the two.

Optionally, the transparent electrode is ito thin film.

Optionally, the diffuser further includes layer glass layer, two layers of glassy layer be respectively arranged on two layers it is described transparent The outside of electrode.

Optionally, the structured light projection instrument includes random array light source and the light emission side set on the random array light source Multiple grating lens, the luminous point that respectively goes out of each grating lens and the random array light source corresponds；The grating is saturating Mirror includes the gratings strips on the surface of substrate and multiple intervals set on the substrate, and the refractive index of the gratings strips is greater than the substrate Refractive index；

When the gratings strips are straight-bar-shaped structure, the position of each gratings strips and phase are all satisfied formula (I)：

Wherein, x is the position of the gratings strips, and f is focal length, and λ is wavelength, and φ (x) is the phase of the gratings strips, φ_max It is the maximum phase variation of the gratings strips；

When the gratings strips are cyclic structure, the position of each gratings strips and phase are all satisfied formula (II)：

Wherein, r is the radius of the gratings strips, and φ (r) is the phase of the gratings strips, φ_maxBe the gratings strips most Big phase change, r_maxIt is the maximum radius of the gratings strips.

Optionally, when the gratings strips are straight-bar-shaped structure, the position of each gratings strips and phase are all satisfied formula (III)：

Wherein, x, y be the gratings strips position and x direction it is vertical with y direction, f is focal length, and λ is wavelength, φ (x, y) is the phase of the gratings strips, φ_maxIt is the maximum phase variation of the gratings strips.

Optionally, the opposite both sides of the face of the substrate are respectively equipped with one layer of gratings strips, and two layers of gratings strips The sum of focal length it is identical as the thickness of the substrate.

Detailed description of the invention

Fig. 1 is the structural schematic diagram of the diffuser of the 3D camera of the embodiment of the present invention；

Fig. 2 is structural schematic diagram of the diffuser under dispersal pattern in Fig. 1；

Fig. 3 is structural schematic diagram of the diffuser under transparent mode in Fig. 1；

Fig. 4 is the structural schematic diagram of structured light projection instrument in Fig. 1；

Fig. 5 is the first setting schematic diagram of each gratings strips when gratings strips are straight-bar-shaped structure in Fig. 4；

Fig. 6 is phase distribution figure corresponding to each gratings strips in Fig. 5；

Fig. 7 is each second of setting schematic diagram of gratings strips when gratings strips are straight-bar-shaped structure in Fig. 4；

Fig. 8 is the structural schematic diagram of the grating lens in Fig. 4 equipped with two layers of gratings strips；

Fig. 9 is the structural schematic diagram of grating lens when gratings strips are cyclic structure in Fig. 4.

In attached drawing 1-9, the reference numerals are as follows：

1- structured light projection instrument, the random array light source of 11-；12- grating lens, 121- gratings strips, 122- first layer grating Item, 123- second layer gratings strips；124- matrix；13- incident beam；14- outgoing beam；

2- diffuser, 21- diffusion barrier, 22- transparent electrode, 23- glassy layer.

Specific embodiment

It is with reference to the accompanying drawing and specific real in order to make those skilled in the art more fully understand technical solution of the present invention Applying example, the present invention is described in further detail.

Fig. 1-3 is please referred to, Fig. 1 is the structural schematic diagram of the diffuser of the 3D camera of the embodiment of the present invention；Fig. 2 is Fig. 1 Structural schematic diagram of the middle diffuser under dispersal pattern；Fig. 3 is structural schematic diagram of the diffuser under transparent mode in Fig. 1.

The embodiment of the invention provides a kind of 3D cameras comprising structured light projection instrument 1, infrared camera, RGB camera shooting Head and diffuser 2, wherein as shown in Figure 1, the diffuser 2 is including two layers of transparent electrode 22 and is located in two layers of transparent electrode Diffusion barrier 21 between 22, and the material of the diffusion barrier 21 is liquid crystal/polymer composite materials.Diffuser 2 is thrown set on structure light The light emission side of shadow instrument 1, the diffusion barrier 21 is in transparent mode under pressurised conditions, which goes out to structured light projection instrument 1 Light does not influence, at this point, structured light projection instrument 1 can issue random array light to target object through diffuser 2, and is being not pressurized In the state of the diffusion barrier 21 be in dispersal pattern, structured light projection instrument 1 can be issued by diffuser 2 to target object uniform Light；RGB camera in bright light environments for capturing the 2D image of target object surface；Infrared camera is used for according to object The random dot matrix photogenerated depth image in body surface face, also, in a dark environment, which can be in the work of uniform light With the lower 2D image for capturing target object surface.

Nematic crystal is rod-like molecule, and optics and dielectric is presented respectively to different due to its anisotropic molecular structure Property, liquid crystal/polymer composite materials are made of liquid crystal and polymer, according to the difference of monomer concentration, liquid crystal/polymer composite wood Material can be divided into three categories：Polymer dispersed liquid crystals, polymer stabilized nematic liquid crystals and polymer network liquid crystal, wherein polymer dispersion Liquid crystal by higher percent monomer (>20wt%) form, and polymer stabilized nematic liquid crystals by lower percentage monomer (< It 10wt%) forms, polymer network liquid crystal is made of the monomer (10wt%~20wt%) of moderate percentages.Due to polymeric web The Anchoring Effect of network, polymer dispersed liquid crystals, polymer stabilized nematic liquid crystals and polymer network liquid crystal are compared with pure nematic crystal The comparatively faster response time is provided, greater flexibility and richer function are provided.

The diffusion barrier 21 of liquid crystal/polymer composite materials is placed between two layers of transparent electrode 22, it can be by diffusion Film 21 applies voltage to change the optical characteristics of this layer of liquid crystal/polymer composite materials.When to 2 making alive of diffuser, liquid Along direction of an electric field, diffusion barrier 21 is in transparent mode (as shown in Figure 3), is equivalent to transparent material layer in brilliant direction, from And structure light is made to pass through liquid crystal layer without scattering, structure light does not have any change.When voltage is not added in diffuser 2, liquid Brilliant direction random distribution, diffusion barrier 21 are in dispersal pattern (as shown in Figure 2), are scattered when structure light passes through liquid crystal layer, from And it is equivalent to and incident light is diffused into equally distributed illumination (i.e. above-mentioned uniform light) output.

Specifically, diffuser 2 is in alive situation when being measured by the 3D camera to the depth of target object Under, diffusion barrier 21 is in transparent mode, and structured light projection instrument 1 can be directed through the diffuser 2 and send out on the surface of target object Random array light out, infrared camera measures the illumination patterns situation on the surface of target object, and is had in conjunction with random array light Some specific distribution situations generate the depth image of target object；And two are divided into for the capture of the 2D image of target object surface Kind of situation, the first situation are can to capture the 2D image of target object surface by RGB camera in bright light environments, second Kind situation is that in a dark environment, diffuser 2 is in the case where being not added voltage, as shown in Fig. 2, diffusion barrier 21 is in diffusion mould Formula, the random array light that structured light projection instrument 1 is issued are radiated at the equal of target object surface by scattering by the diffuser 2 Even light under the illumination of uniform light, passes through infrared camera at this point, the uniform light of structured light projection instrument 1 only plays illuminating effect The 2D image of target object surface can be captured；Finally, being produced according to the depth image of target object surface and 2D image The 3D rendering of the target object.

Diffusion barrier 21 is selected to be in transparent mode or dispersal pattern, the expansion by the way that whether electricity control diffuser 2 pressurizes The setting for dissipating device 2 does not influence the acquisition of depth image, also, when acquiring the 2D image of target object surface, the diffusion Device 2 can also make structured light projection instrument 1 play illuminating effect, without in addition setting illuminace component (such as infrared washers Deng), that is to say, that by the setting of the diffuser 2, so that structured light projection instrument 1 can not only issue at random to target object Array light, while also having both the function of illumination, the overall structure of the 3D camera can be simplified and being conducive to the miniaturization of 3D camera. Simultaneously because the thinner thickness of diffusion barrier 21 and transparent electrode 22, small volume, be readily integrated to structured light projection instrument 1 goes out light Side, in the present embodiment with no restrictions for the connection between structured light projection instrument 1 and diffuser 2, such as can by being glued or The fixation of the realizations such as the clamping of other mechanical parts position between the two.

In the above-described embodiments, transparent electrode 22 is ito thin film, and ito thin film is indium tin oxide transparent conductive semiconductor Film, the transparency and electric conductivity are good, can reduce the thickness of diffuser 2 under the premise of meeting same conductivity, and then simplify Overall structure is conducive to the miniaturization of the 3D camera.Certainly, in the present embodiment, which can also select it Its material, such as graphene, herein with no restrictions.

In the above-described embodiments, diffuser 2 further includes layer glass layer 23, layer glass layer 23 be respectively arranged on two layers it is transparent The outside of electrode 22, due to the thinner thickness of diffusion barrier 21 and transparent electrode 22, the setting of two layers of transparent glassy layer 23 The overall structural strength that can guarantee the diffuser 2, is easily installed.

Fig. 4-9 is please referred to, Fig. 4 is the structural schematic diagram of structured light projection instrument in Fig. 1；Fig. 5 is that gratings strips are vertical bar in Fig. 4 The first setting schematic diagram of each gratings strips when shape structure；Fig. 6 is phase distribution figure corresponding to each gratings strips in Fig. 5；Fig. 7 is figure Each second of setting schematic diagram of gratings strips when gratings strips are straight-bar-shaped structure in 4；Fig. 8 is the light that two layers of gratings strips is equipped in Fig. 4 The structural schematic diagram of grid lens；Fig. 9 is the structural schematic diagram of grating lens when gratings strips are cyclic structure in Fig. 4.

As shown in figure 4, the structured light projection instrument 1 in 3D camera provided by the present embodiment includes random array light source 11 With multiple grating lens 12, wherein random array light source 11 is set to random dot matrix for emitting random array light, grating lens 12 The light emission side of light source 11, and to go out luminous point corresponding with a grating lens 1 for each of random array light source 11.The grating is saturating Mirror 12 includes the gratings strips 121 on the surface of substrate 124 and multiple intervals set on substrate 124, and the refractive index of gratings strips 121 is greater than lining The refractive index at bottom 124.

Specifically, the specific structure of gratings strips 121 is divided to two kinds, the first is that gratings strips 121 are straight-bar-shaped structure, at this point, The position of each gratings strips 121 and phase are all satisfied following formula (I)；

Wherein, x is the position of gratings strips 121, and f is focal length, and λ is wavelength, and φ (x) is the phase of gratings strips 121, φ_maxIt is The maximum phase of gratings strips 121 changes；

Second is that gratings strips 121 are cyclic structure, at this point, the position of each gratings strips 121 and phase are all satisfied following public affairs Formula (II)：

Wherein, r is the radius of gratings strips 121, and φ (r) is the phase of gratings strips 121, φ_maxIt is the maximum of gratings strips 121 Phase change, r_maxIt is the maximum radius of gratings strips 121.

Below for the first, gratings strips 121 carry out expansion explanation when being straight-bar-shaped structure.

Based on geometric optics, the phase distribution of above-mentioned formula (I) is the desired phase distribution of focusing unit, each gratings strips 121 phase is related with its width, position and thickness, and the consistency of thickness of each gratings strips 121, therefore, by each gratings strips 121 Grating lens 12 obtained are set according to above-mentioned formula (I), is equal to and a discrete phase distribution is carried out into approximate ideal phase Distribution.I.e. by the identical but of different size gratings strips 121 of multiple thickness according in above-mentioned formula (I) between phase and the relationship of position Every setting, a focusing unit is formed, is placed on the light emission side of random array light source 11, it being capable of focus on light beam.

Phase is big, then greatly, the focusing capability of lens is strong for numerical aperture (NA).For traditional glass lens, big phase Position needs bigger thickness and radian, realizes more difficult.And in the grating lens 12 in the present embodiment, the phase of gratings strips 121 The size of position φ (x) can be realized by changing the width of the gratings strips 121, be relatively easy to.

Specifically, phase such as Fig. 6 institute as shown in figure 5, the gratings strips 121 of corresponding each position is arranged in gratings strips 121 Show.It is the thickness of each gratings strips 121 identical (being t), of different size, and by intermediate setting outward, wherein the grating in middle position The phase of item 121 is φ (0), in position x₁The phase of the gratings strips 121 at place is φ (x₁), wherein φ (x₁) and x₁Meet above-mentioned Corresponding relationship in formula (I)；Correspondingly, in position x_-1The gratings strips 121 and position x at place₁The gratings strips 121 at place are symmetrical, wide Spend that identical, phase is identical；In position x₂The phase of the gratings strips 121 at place is φ (x₂), wherein φ (x₂) and x₂Meet above-mentioned public affairs Corresponding relationship in formula (I)；Correspondingly, in position x_-2The gratings strips 121 and position x at place₂The gratings strips 121 at place are symmetrical, width It is identical, phase is identical；X is located at above-mentioned for the setting of gratings strips 121 located elsewhere₁Place and x₂121 class of gratings strips Seemingly, details are not described herein.

Gratings strips 121 can realize the change of its phase by changing its width, due to when φ (x) is greater than 2 π or is less than When 0, the phase of gratings strips 121 can be mapped to a value equivalent between 0~2 π, therefore, corresponding for position For the lesser gratings strips 121 of phase, its phase mapping can be made to its institute between 0~2 π the increase of the width of the gratings strips 121 Phase value (phase distribution is serrated in such as Fig. 6, each sawtooth has corresponded to 0~2 section π) is needed, such as Fig. 5 institute Show, the width of gratings strips 121 first reduces from centre to two sides to be increased afterwards, i.e., extra wide is arranged without the variation because of phase or spy is narrow Gratings strips 121, it is ensured that the width of gratings strips 121 changes in a certain range, to simplify the manufacture craft of gratings strips 121.

In the above-described embodiments, the position of the gratings strips 121 of straight-bar-shaped structure and phase relation also meet public formula (III)：

Wherein, x, y be gratings strips 121 position and x direction it is vertical with y direction, f is focal length, and λ is wavelength, φ (x, y) is the phase of the gratings strips 121, φ_maxIt is the maximum phase variation of the gratings strips 121.

At this point, the relationship of the position of the position and y direction of the phase of gratings strips 121 and x direction, i.e. formula (III) facilities of the gratings strips 121 under two-dimensional state are shown.Specifically, the x direction (axis with gratings strips 121 Vertical direction) on each gratings strips 121 phase and positional relationship still meet formula (I), and y direction is (with gratings strips 121 The parallel direction of axis) on position distribution then pass through and change the width of each position of each gratings strips 121 in the y-direction and realize, I.e. each gratings strips 121 along its length on width be not constant (as shown in Figure 7), under such setting, the grating is saturating Mirror 12 can reduce the size of luminous point from orthogonal both direction, and then realize its focusing function.

It, can be as shown in fig. 7, shape with luminous point for the concrete shape of the grating lens 12 in addition, in the present embodiment Consistent disc-shaped structure also can be made square structure, be not particularly limited herein.

Focusing function, such as two by distance in the grating lens 12 farthest can be realized in the lesser grating lens 12 of thickness The distance between gratings strips 121 are set as 10 μm, 3 μm of thickness, pass through the Three-dimensional Time Domain finite difference calculus of Gaussian beam incidence (FDTD) it is 3.5 μm that simulation result, which is the beam waist radius of incident beam 1, and after being focused by grating lens 12, beam waist radius is 0.89 μm, i.e. outgoing beam 14 increases 12 times compared to 13 central light strength of incident beam.Relatively thin grating lens 12 are easy to single Piece is integrated in random array light source 11 so that the overall structure of the structured light projection instrument 1 be easier to miniaturization, it is integrated.

In the above-described embodiments, the opposite both sides of the face of substrate 124 are respectively equipped with one layer of gratings strips 121, that is to say, that one Two layers of gratings strips 121 are shared, the opposite both sides of the face of substrate 124 are respectively arranged on, two layers of gratings strips, 121 position and phase Setting meets above-mentioned formula (III) respectively, and the sum of focal length of two layers of gratings strips 121 is identical as the thickness of substrate 124.Specifically , as shown in figure 8, the focal length of first layer gratings strips 122 is f₁, the focal length of second layer gratings strips 123 is f₂, the thickness of substrate 124 For d, work as f₁+f₂When=d, incident beam 13 successively be can be realized after first layer gratings strips 122 and second layer gratings strips 123 Outgoing beam 14 is collimated, so that the radius of outgoing beam 14 becomes smaller, the multiple which reduces is

Due to the thickness very little of grating lens 12, and the grating lens 12 by designing higher NA, focal length f₁And f₂It can be with It is designed very little, so that the thickness d of substrate 124 also very little.In this way, we can be obtained by the very small standard of integral thickness Straight device, to realize the miniaturization of structured light projection instrument 1 and integrated.

Below for second, gratings strips 121 carry out expansion explanation when being cyclic structure (as shown in Figure 9).

Ideal bessel beam does not have any diffraction, and regardless of propagating, how far beam size be will not change.But due to ideal The energy of bessel beam is unlimited, so can not be achieved ideal bessel beam in practical applications.Bezier Gauss Light beam is similar to bessel beam, the beam size Gaussian beam far smaller than common with the variation of propagation.In the prior art, Incident beam 13 can be converted into Bessel-Gaussian beam by axicon lens.

In the present embodiment, according to above-mentioned formula (II), each gratings strips 121 are set as to the cyclic structure of coaxial arrangement, at this point, When incident beam 13 is after grating lens 12, incident beam 13 is collimated to become Bessel-Gaussian beam, thus beam size With the far smaller than common Gaussian beam of the variation of propagation.This characteristic collimates very the random array light of medium and long distance Favorably.

In the present embodiment, the consistency of thickness of each gratings strips 121 and relatively thin, i.e. grating lens 12 are a two-dimensional structure, should The thickness of grating lens 12 is far smaller than the thickness of axicon lens, convenient for being integrated in random array light source 11 and being easily achieved miniature Change.

That is, in the embodiment of the present invention, for aperiodicity grating lens 12, the thickness of each gratings strips 121 Unanimously, there are different width and gap length without same gratings strips 121.Specifically, gratings strips 121 can be straight-bar-shaped structure, As shown in figure 5, each interval setting side by side of gratings strips 121, (only sets at this point, the grating lens 12 can be used for focusing incident beam 13 Have one layer of gratings strips 121), it can also be used to collimated incident beam 13 (is equipped with two layers of gratings strips 121)；Gratings strips 121 are also possible to Cyclic structure, at this point, the grating lens 12, which can be used for for incident beam 13 being collimated, becomes Bessel-Gaussian beam.It specifically can root It is configured according to needs.

In addition, the grating lens 12 in the present embodiment can be made up of common photoetching technique, production is simple, at low cost, Also, it is corresponding with the position of luminous point out due to having photolithographic structures inside random array light source 11, when assembling, by grating The photo-etching mark of lens 12 is aligned with the photolithographic structures of random array light source 11, and alignment function can be completed, and is operated relatively simple.

Certainly, in the present embodiment, structured light projection instrument 1 can also be made of random array light source 11 and glass lens, Specific requirement is not done herein.

In the above-described embodiments, random array light source 11 can be set to include laser and diffraction optical device knot Structure can also set random array light source 11 in the laser of multiple random distributions, be not particularly limited herein, as long as energy So that the random array light source 11 launches random array light.

In the above-described embodiments, the difference of the refractive index of gratings strips 121 and the refractive index of substrate 124 is not less than 1, Ci Zhongshe It sets for the case where refractive index difference of the two is less than 1, can be further reduced in the case where focal length having the same The thickness of the grating lens 12, conducive to realize overall structure be easier to miniaturization, it is integrated.

In the above-described embodiments, the material of gratings strips 121 is set as silicon, the material of substrate 124 can be set to silica Or the material of gratings strips 121 can also be such as set as silicon nitride herein with no restrictions by silicon nitride, the material of substrate 124 is set For silica etc..As long as can guarantee that the refractive index of gratings strips 121 is greater than the refractive index of substrate 124 to realize the remittance of light beam It is poly-, and the two will not cause obstruction to the propagation of light beam.

The above is only the preferred embodiment of the present invention, it is noted that those skilled in the art are come It says, various improvements and modifications may be made without departing from the principle of the present invention, these improvements and modifications also should be regarded as Protection scope of the present invention.

Claims

1. a kind of 3D camera, which is characterized in that including structured light projection instrument (1), infrared camera, RGB camera and diffusion Device (2)；

The diffuser (2) includes two layers of transparent electrode (22) and the diffusion being located between two layers of transparent electrode (22) Film (21), the material of the diffusion barrier (21) are liquid crystal/polymer composite materials；

The diffuser (2) is set to the light emission side of the structured light projection instrument (1), diffusion barrier in the state of making alive (21) transparent mode, the structured light projection instrument (1) can issue random dot matrix to target object through the diffuser (2) Light；In the state that voltage is not added, the diffusion barrier (21) is in dispersal pattern, and the structured light projection instrument (1) can pass through institute It states diffuser (2) and issues uniform light to the target object；

The RGB camera is used to capture the 2D image of the target object surface in bright light environments；

The infrared camera is used for the random dot matrix photogenerated depth image according to target object surface, and in dark ring The 2D image of the target object surface is captured in border under the uniform light.

2. 3D camera according to claim 1, which is characterized in that the transparent electrode (22) is ito thin film.

3. 3D camera according to claim 2, which is characterized in that the diffuser (2) further includes layer glass layer (23), two layers of glassy layer (23) is respectively arranged on the outside of two layers of transparent electrode (22).

4. 3D camera according to claim 1-3, which is characterized in that the structured light projection instrument includes random Multiple grating lens (12) of array light source (11) and the light emission side set on the random array light source (11), each grating are saturating Mirror (12) and the luminous point that respectively goes out of the random array light source (11) correspond；

The grating lens (12) include the gratings strips on the surface of substrate (124) and multiple intervals set on the substrate (124) (121), the refractive index of the gratings strips (121) is greater than the refractive index of the substrate (124)；

When the gratings strips (121) are straight-bar-shaped structure, the position of each gratings strips (121) and phase are all satisfied formula (I)：

Wherein, x is the position of the gratings strips (121), and f is focal length, and λ is wavelength, and φ (x) is the phase of the gratings strips (121) Position, φ_maxIt is the maximum phase variation of the gratings strips (121)；

When the gratings strips (121) are cyclic structure, the position of each gratings strips (121) and phase are all satisfied formula (II)：

Wherein, r is the radius of the gratings strips (121), and φ (r) is the phase of the gratings strips (121), φ_maxIt is the grating The maximum phase of item (121) changes, r_maxIt is the maximum radius of the gratings strips (121).

5. 3D camera according to claim 4, which is characterized in that when the gratings strips (121) are straight-bar-shaped structure, respectively The position of the gratings strips (121) and phase are all satisfied public formula (III)：

Wherein, x, y be the gratings strips (121) position and x direction it is vertical with y direction, f is focal length, and λ is wave Long, φ (x, y) is the phase of the gratings strips (121), φ_maxIt is the maximum phase variation of the gratings strips (121).

6. 3D camera according to claim 5, which is characterized in that the opposite both sides of the face difference of the substrate (124) Equipped with one layer of gratings strips (121), and thickness of the sum of the focal length of two layers of gratings strips (121) with the substrate (124) It is identical.